Tyrosine O-sulfation, catalyzed by tyrosylprotein sulfotransferases (TPST, EC 2.8.2.20), is a post-translational modification, which transfers a moiety of sulfuryl group from 3’-phosphoadenosine 5’-phosphosulfate (PAPS) to specific tyrosine residues within polypeptides. Protein tyrosine sulfation regulates many important physiological and pathological functions including inflammation, chemokine signaling, and virus entry. In this dissertation, I developed feasible biochemical tools and a sulfoproteomics platform to comprehend TPST actions and biological functions. Firstly, a heterologous TPST expression system and purification procedure was developed to produce the enzymatically active recombinant TPSTs at near homogeneity. An in situ PAPS generating system was further established to efficiently determine the activities of recombinant TPSTs. Our data indicated that the combination of in situ PAPS generating system with TPST-catalyzed reaction significantly improved the apparent productive rate of tyrosine-sulfated proteins over 40-fold magnitude. A single point mutation, H269Q of Drosophila melanogaster TPST which resulted in dwarfism-associated hypothyroidism, would contribute to weak enzyme activity. Detailed mechanism regarding structure-function relationship was discussed. Furthermore, TPST-knockdowned D. melanogaster was generated and investigated using the biochemical tools developed in this research and conventional proteomics technology. By the identified proteins in proteomics process and the stress paradigm of paraquat treatment and dietary restriction, the TPST-deficient flies were confirmed to be labile under both stresses of oxidation and starvation. This research provides feasible biochemical tools and pioneering sulfoproteomics approach to uncover the significance of protein tyrosine sulfation from molecular level to a complex organism.